Applied Mathematical Modeling for Biomedical Robotics and Wearable Devices

Applied Mathematical Modeling for Biomedical Robotics and Wearable Devices by S. Sountharrajan draws you in with a clear promise: rigorous mathematics applied to the real-world challenges of biomedical robotics and wearable technology. Whether you’re an engineer in Boston, a clinician in London, or a researcher in Bangalore, this book bridges theory and practice with crisp, accessible presentation.

Inside, you’ll find focused coverage of mathematical tools that power modern biomedical systems — differential equations, finite element modeling, system identification, control theory, optimization, and data-driven approaches for sensor fusion. Emphasis on biomechanics, soft-robotic actuators, prosthetics, exoskeleton control, and wearable sensor modeling makes the content directly relevant to designers and researchers working on mobility aids, rehabilitation devices, and health-monitoring wearables.

Each chapter translates abstract concepts into practical workflows: model formulation, parameter estimation, simulation strategies, and validation against experimental data. Case studies and applied examples demonstrate how modeling accelerates prototyping, improves control robustness, and enhances patient-centered design. The text is written to serve graduate students, R&D engineers, and interdisciplinary teams in academia and industry.

If you’re developing wearable health systems or biomedical robots and want a dependable mathematical foundation that connects to implementation, this book delivers. It helps you reduce development risk, interpret sensor outputs, and design controllers that perform reliably in human-centered environments.

Add Applied Mathematical Modeling for Biomedical Robotics and Wearable Devices by S. Sountharrajan to your professional library — an essential resource for anyone shaping the future of medical devices and wearable technologies across global innovation hubs. Explore, model, and build with confidence.

Note: eBooks do not include supplementary materials such as CDs, access codes, etc.